Endoscopic device

ABSTRACT

There is provided an endoscopic device, including: an image sensor section including an image sensor that senses and converts lights into an electrical signal; a substrate that is electrically connected to the image sensor section; and an intermediate unit, interposed between the image sensor section and the substrate, that electrically connects the image sensor section and the substrate.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of Japanese Priority PatentApplication JP 2015-248860 filed Dec. 21, 2015, the entire contents ofwhich are incorporated herein by reference.

BACKGROUND

The present disclosure relates to an endoscopic device.

Heretofore, in the medical field, there are known endoscopic devicesthat use an image sensor to image the interior (the inside of the body)of a target of observation, such as a person, and enable observation ofthe inside of the body (see JP 2011-000346A, for example). Theendoscopic device described in JP 2011-000346A is equipped with an imagesensor that captures a subject image in which light has been condensedby an insertion section inserted inside the body, and a drive circuitboard for driving the image sensor. In the endoscopic device, therelative positions of the image sensor and the drive circuit board arefixed by a spacer.

SUMMARY

Meanwhile, in some cases, the endoscopic device disclosed by JP2011-000346A may be exposed to high temperature (120° C., for example)by a sterilization process, such as with an autoclave. In such cases,since components such as the image sensor, the drive circuit board, andthe spacer provided in the endoscopic device are exposed to hightemperature, each of these components undergoes thermal expansion.However, in JP 2011-000346A, this thermal expansion is not considered,and because of the respective stresses imparted to the joint interfaceswith the spacer due to differences in the individual coefficients ofthermal expansion, there is a risk of a faulty electrical connectionoccurring between the image sensor and the drive circuit board.

The present disclosure has been devised in light of the above, andprovides an endoscopic device capable of making a reliable electricalconnection between an image sensor and a substrate, even when exposed tohigh temperature.

According to an embodiment of the present disclosure, there is providedan endoscopic device, including: an image sensor section including animage sensor that senses and converts lights into an electrical signal;a substrate that is electrically connected to the image sensor section;and an intermediate unit, interposed between the image sensor sectionand the substrate, that electrically connects the image sensor sectionand the substrate.

The intermediate unit may include an intermediate member formed using amaterial having a coefficient of thermal expansion that is the same as acoefficient of thermal expansion of the image sensor section, or acoefficient of thermal expansion that is close to the coefficient ofthermal expansion of the image sensor section from between the imagesensor section and the substrate.

The intermediate unit may additionally include solder balls thatelectrically connect the intermediate member and the substrate, andunderfill, provided between the intermediate member and the substrate,that secures the intermediate member and the substrate.

The endoscopic device may further include: solder balls thatelectrically connect the image sensor section and the intermediatemember.

The intermediate unit may include an electrically conductive,elastically deformable elastic member provided between the image sensorsection and the substrate.

The intermediate unit may include an intermediate member formed using amaterial having a coefficient of thermal expansion that is the same as acoefficient of thermal expansion of the image sensor section, or acoefficient of thermal expansion that is close to the coefficient ofthermal expansion of the image sensor section from between the imagesensor section and the substrate, and an electrically conductive elasticmember, provided between the intermediate member and the substrate, thatretractably connects the intermediate member and the substrate from oneto the other.

According to an embodiment of the present disclosure, there is exhibitedan advantageous effect of making a reliable electrical connectionbetween an image sensor and a substrate, even when exposed to hightemperature.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram illustrating a schematic configuration of anendoscopic device according to Embodiment 1 of the present disclosure;

FIG. 2 is a block diagram illustrating a configuration of the camerahead and the control device illustrated in FIG. 1;

FIG. 3 is a schematic diagram explaining the major configuration of animaging section according to Embodiment 1 of the present disclosure;

FIG. 4 is a schematic diagram explaining the major configuration of animaging section according to Modification 1 of Embodiment 1 of thepresent disclosure;

FIG. 5 is a schematic diagram explaining the major configuration of animaging section according to Modification 2 of Embodiment 1 of thepresent disclosure;

FIG. 6 is a schematic diagram explaining the major configuration of animaging section according to Modification 3 of Embodiment 1 of thepresent disclosure;

FIG. 7 is a diagram illustrating a schematic configuration of anendoscopic device according to Embodiment 2 of the present disclosure;

FIG. 8 is a diagram illustrating a schematic configuration of anendoscopic device according to Embodiment 2 of the present disclosure;

FIG. 9 is an exploded perspective diagram of a plug and a receptacle asviewed from base end side (camera head side) of the plug;

FIG. 10 is a cross-section view cut along a plane passing through acentral axis in the direction in which a plug and a receptacle connect;

FIG. 11 is a diagram illustrating a major configuration of an endoscopicdevice according to Embodiment 3 of the present disclosure; and

FIG. 12 is a diagram illustrating a major configuration of an endoscopicdevice according to Embodiment 3 of the present disclosure.

DETAILED DESCRIPTION OF THE EMBODIMENT(S)

Hereinafter, embodiments for carrying out the present disclosure(hereinafter designated the exemplary embodiments) will be described. Inthe embodiments, an endoscopic device for medical use that captures anddisplays an interior image of a test subject such as a patient will bedescribed as an example of a medical image acquisition system includinga medical imaging device according to an embodiment of the presentdisclosure. In addition, the present disclosure is not limited by theseembodiments. Furthermore, in the description of the drawings, likeportions are denoted by like signs.

(Embodiment 1)

FIG. 1 is a diagram illustrating a schematic configuration of anendoscopic device 1 according to Embodiment 1 of the present disclosure.The endoscopic device 1 is a device used in the medical field thatenables one to observe a photographic subject of the interior (theinside of the body) of a target of observation, such as a person. Asillustrated in FIG. 1, the endoscopic device 1 is equipped with anendoscope 2, an imaging device 3, a display device 4, a control device5, and a light source device 6.

One end of a light guide 7 is connected to the endoscope 2, and thelight source device 6 supplies white illuminating light for illuminatingthe inside of the body to the one end of the light guide 7. One end ofthe light guide 7 is removably connected to the light source device 6,while the other end is removably connected to the endoscope 2.Additionally, the light guide 7 transmits light supplied from the lightsource device 6 from the one end to the other end, thereby supplying thelight to the endoscope 2.

The imaging device 3 captures a subject image from the endoscope 2, andoutputs the imaging result. As illustrated in FIG. 1, the imaging device3 is equipped with a transmission cable 8 which acts as a signaltransmission section, and a camera head 9. In Embodiment 1, the medicalimaging device is constituted by the transmission cable 8 and the camerahead 9.

The endoscope 2 has a rigid, long and narrow shape, and is insertedinside the body. Provided in the interior of the endoscope 2 is anoptical system, which is made up of one or multiple lenses, and whichcondenses the light of the subject image. The endoscope 2 emits lightsupplied through the light guide 7 from the leading end, and irradiatesthe inside of the body. Additionally, the light radiated inside the body(that is, the subject image) is condensed by the optical system (lensunit 91) inside the endoscope 2.

The camera head 9 is removably connected to the base end of theendoscope 2. Additionally, the camera head 9, under control by thecontrol device 5, captures a subject image condensed by the endoscope 2,and outputs an imaging signal according to the imaging. Note that thedetailed configuration of the camera head 9 will be discussed later.

One end of the transmission cable 8 is removably connected to thecontrol device 5 through a connector, while the other end is removablyconnected to the camera head 9 through a connector. Specifically, thetransmission cable 8 is a cable in which multiple electrical wires (notillustrated) are arranged inside the inner part of an outer sheath thatacts as the outermost layer. The multiple electrical wires areelectrical wires for transmitting the imaging signal output from thecamera head 9, as well as a control signal, a synchronization signal, aclock, and power output from the control device 5 to the camera head 9,respectively.

The display device 4, under control by the control device 5, displays animage generated by the control device 5. The display device 4 preferablyincludes a display of at least 55 inches to achieve a sense of immersionmore easily during observation, but is not limited thereto.

The control device 5 processes the imaging signal input from the camerahead 9 through the transmission cable 8, and outputs an image signal tothe display device 4. In addition, the control device 5 also centrallycontrols the operations of the camera head 9 and the display device 4.Note that the detailed configuration of the control device 5 will bediscussed later.

Next, a configuration of the imaging device 3 and the control device 5will be described. FIG. 2 is a block diagram illustrating aconfiguration of the imaging device 3 and the control device 5. Notethat in FIG. 2, the connector that allows the camera head 9 and thetransmission cable 8 to be removably connected to each other is omittedfrom illustration.

Hereinafter, the configuration of the control device 5 and theconfiguration of the camera head 9 will be described in order. Note thatin the following, the gist of the present disclosure is describedprimarily as the configuration of the control device 5. As illustratedin FIG. 2, the control device 5 is equipped with a signal processingsection 51, an image generation section 52, a communication module 53,an input section 54, a control section 55, and memory 56. Note that thecontrol device 5 may also be provided with components such as a powersupply section (not illustrated) that generates a power supply voltagefor driving the control device 5 and the camera head 9 and respectivelysupplies the power supply voltage to each component of the controldevice 5, while also supplying the power supply voltage to the camerahead 9 through the transmission cable 8.

The signal processing section 51 performs signal processing such asnoise removal, and if necessary, A/D conversion, on the imaging signaloutput by the camera head 9, and outputs a digitized imaging signal(pulse signal) to the image generation section 52.

Additionally, the signal processing section 51 generates asynchronization signal for the imaging device 3 and the control device5, and a clock. The synchronization signal for the imaging device 3(such as a synchronization signal indicating the imaging timings of thecamera head 9, for example) and the clock (a clock used for serialcommunication, for example) are sent to the imaging device 3 on a linenot illustrated, and the imaging device 3 drives on the basis of thesynchronization signal and the clock.

The image generation section 52 generates a display image signal to bedisplayed by the display device 4, based on the imaging signal inputfrom the signal processing section 51. The image generation section 52executes certain signal processing on the imaging signal to generate adisplay image signal that includes the subject image. Herein, the imageprocessing may be any of various types of image processing, such asinterpolation processing, color correction processing, color enhancementprocessing, and edge enhancement processing. The image generationsection 52 outputs the generated image signal to the display device 4.

The communication module 53 outputs, to the imaging device 3, a signalfrom the control device 5 including a control signal discussed laterthat is transmitted from the control section 55. The communicationmodule 53 also outputs a signal from the imaging device 3 to the controldevice 5. In other words, the communication module 53 is a relay devicethat outputs the signals from the respective components of the controldevice 5 to the imaging device 3 in a collective manner, such as byparallel-serial conversion, for example, and also outputs a signal inputfrom the imaging device 3 to the respective components of the controldevice 5 in a distributed manner, such as by serial-parallel conversion,for example.

The input section 54 is realized using a user interface such as akeyboard, a mouse, or a touch panel, and accepts the input of variousinformation.

The control section 55 performs controls such as drive control of eachcomponent, including the control device 5 and the camera head 9, andinput/output control of information with respect to each component. Thecontrol section 55 generates a control signal by referencingcommunication information data recorded in the memory 56 (such ascommunication format information, for example), and transmits thegenerated control signal to the imaging device 3 through thecommunication module 53. The control section 55 also outputs a controlsignal to the camera head 9 through the transmission cable 8.

The memory 56 is realized using semiconductor memory such as flashmemory or dynamic random access memory (DRAM), and records communicationinformation data (such as communication format information, forexample). Note that the memory 56 may also record information such asvarious programs executed by the control section 55.

Note that the signal processing section 51 may also include an AFprocessing section that outputs a certain AF score value for each framebased on an input frame imaging signal, and an AF computation sectionthat performs an AF computational process of selecting the frame or thefocus lens position best suited as the focus position, based on the AFscore value of each frame from the AF processing section.

Note that the signal processing section 51, the image generation section52, the communication module 53, and the control section 55 discussedabove are realized by a general-purpose processor such as a centralprocessing unit (CPU) including internal memory (not illustrated) inwhich a program is recorded, or by a special-purpose processor such asany of various types of computational circuits that execute a specificfunction, such as an application-specific integrated circuit (ASIC).Additionally, a field-programmable gate array (FPGA; not illustrated),which is a type of programmable integrated circuit, may also be used torealize the above. Note that in the case of using an FPGA, memorystoring configuration data may be provided, and the FPGA, that is, theprogrammable integrated circuit, may be configured according toconfiguration data read out from the memory.

Next, the gist of the present disclosure will be described primarily asthe configuration of the camera head 9. As illustrated in FIG. 2, thecamera head 9 is equipped with a lens unit 91, an imaging section 92, adrive section 93, a communication module 94, and a camera head controlsection 95.

The lens unit 91 is configured using one or multiple lenses, and forms asubject image condensed by the endoscope 2 onto the imaging surface ofan image sensor constituting the imaging section 92. The one or multiplelenses are movably configured along the optical axis. Additionally, thelens unit 91 is provided with a focus mechanism that moves the one ormultiple lenses to vary an optical zoom mechanism (not illustrated) thatvaries the angle of view, or the focus point. Note that, besides theoptical zoom mechanism and the focus mechanism, the lens unit 91 mayalso be provided with a diaphragm mechanism, or an optical filter (forexample, a filter that cuts infrared light) that may be freely insertedor removed from the optical axis.

The imaging section 92 images a subject, under control by the camerahead control section 95. The imaging section 92 includes an image sensormade of a device such as a charge-coupled device (CCD) or acomplementary metal-oxide-semiconductor (CMOS) that senses the light ofa subject image formed by the lens unit 91, and converts the light intoan electrical signal. In the CCD case, for example, a signal processingsection (not illustrated) that performs signal processing (such as A/Dconversion) on the electrical signal (analog signal) from the imagesensor and outputs an imaging signal is implemented in a sensor chip orthe like. In the CMOS case, for example, a signal processing sectionthat performs signal processing (such as A/D conversion) on an (analog)electrical signal converted from light into an electrical signal andoutputs an imaging signal is included in the image sensor.

FIG. 3 is a schematic diagram explaining the major configuration of theimaging section 92. As illustrated in FIG. 3, the imaging section 92includes an image sensor 101, a holding unit 102, an intermediate unit103, a land grid array (LGA) 104, and a substrate 110. A lens adapter120 is provided on the holding unit 102, and the imaging section 92 isattached to the lens unit 91 by the lens adapter 120. In the imagingsection 92, observational light from outside the lens unit 91 isincident on the image sensor 101 through the lens unit 91. In Embodiment1, the substrate 110 is taken to be formed using an organic materialhaving a coefficient of thermal expansion from 12 ppm/° C. to 40 ppm/°C. in the direction along the mounting face at room temperature. InEmbodiment 1, an image sensor section 100 is constituted by the imagesensor 101 and the holding unit 102.

The image sensor 101 is realized using the CCD or CMOS discussed above.In the image sensor 101, multiple pixels that sense light from the lensunit 91 are arranged in a two-dimensional grid (arranged in a matrix).Additionally, the image sensor 101 generates an electrical signal (alsocalled an image signal or the like) by performing photoelectricconversion on the light sensed by each of the pixels.

The image sensor 101 is electrically connected to the substrate 110, andincludes a built-in circuit section that transmits and receives signalsto and from the substrate 110.

The holding unit 102 forms a housing that holds the image sensor 101inside. The holding unit 102 includes a holding section 102 a, a ringsection 102 b, and a cap section 102 c.

The holding section 102 a forms a tube with a floor on one end, andholds the image sensor 101 in the floor section. The holding section 102a has a smaller coefficient of thermal expansion than the substrate 110,and is formed using a ceramic having a coefficient of thermal expansionfrom 4 ppm/° C. to 11 ppm/° C. in the direction along the mounting faceat room temperature, for example.

The holding unit 102 forms a ring extending from open end of the holdingsection 102 a. The ring section 102 b is formed using a resin such asplastic, for example.

The cap section 102 c has a plate-like shape, and is provided on theedge of the ring section 102 b on the opposite side from the holdingsection 102 a. With the cap section 102 c, the opening in the flooredtube formed by the holding section 102 a and the ring section 102 b issealed. The cap section 102 c is formed using an optically transparentmaterial, such as glass, for example.

Note that in Embodiment 1, the image sensor section 100 is constitutedby the image sensor 101 and the holding unit 102, but the configurationis not limited thereto, and the image sensor section 100 may also beconstituted by the image sensor 101 only, for example.

The intermediate unit 103 is provided between the image sensor section100 and the substrate 110. The intermediate unit 103 includes anintermediate member 103 a, solder balls 103 b, and underfill 103 c.

The intermediate member 103 a is provided internally with electricalinterconnects, enabling an electrical connection between the imagesensor 101 and the substrate 110. The intermediate member 103 a may be acircuit board using a material such as ceramic, silicon, glass, or glassfiber reinforced epoxy resin as a substrate, for example, but is notlimited thereto. The intermediate member 103 a is formed using amaterial having the same coefficient of thermal expansion as the imagesensor section 100, or a material having a coefficient of thermalexpansion that is close to the image sensor section 100 from between theimage sensor section 100 and the substrate 110. Specifically, theintermediate member 103 a is formed using a material having acoefficient of thermal expansion whose value is 95% or greater than thecoefficient of thermal expansion of the holding section 102 a, and alsoless than or equal to an intermediate value between the coefficient ofthermal expansion of the holding section 102 a and the coefficient ofthermal expansion of the substrate 110.

The solder balls 103 b are provided between the intermediate member 103a and the substrate 110. The solder balls 103 b transmit signals fromthe substrate 110 to the intermediate member 103 a, and also transmitsignals from the intermediate member 103 a to the substrate 110.

The underfill 103 c surrounds the solder balls 103 b and fills in thespace between the intermediate member 103 a and the substrate 110, andpreferably fills in the space to cover the solder balls 103 b withoutgaps, but is not limited thereto. The underfill 103 c is a material withless elasticity than the intermediate member 103 a and the substrate110. The underfill 103 c preferably is a material having a glasstransition temperature of 120° C. or more, but is not limited thereto.The underfill 103 c is formed using a material having a coefficient ofthermal expansion from 30 ppm/° C. to 50 ppm/° C. at room temperatureafter hardening, for example. The underfill 103 c fixes the intermediatemember 103 a and the substrate 110 in place, and in addition, bysurrounding the solder balls 103 b, reduces corrosion of the solderballs 103 b. Note that the underfill 103 c may also be formed using amaterial having a coefficient of thermal expansion with a value betweenthe coefficient of thermal expansion of the intermediate member 103 aand the coefficient of thermal expansion of the substrate 110.

The land grid array (LGA) 104 is realized using multiple flat electrodepads that electrically connect the image sensor section 100 and theintermediate unit 103.

The drive section 93 includes a driver that, under control by the camerahead control section 95, causes the optical zoom mechanism and the focusmechanism to operate, and varies the angle of view and the focusposition of the lens unit 91.

The communication module 94 outputs signals transmitted from the controldevice 5 to respective components inside the camera head 9, such as thecamera head control section 95. Additionally, the communication module94 converts information related to the current state of the camera head9 and the like into a signal format according to a predeterminedtransmission scheme, and outputs the converted signal to the controldevice 5 through the transmission cable 8. In other words, thecommunication module 94 is a relay device that outputs a signal inputfrom the control device 5 and the transmission cable 8 to respectivecomponents of the camera head 9 in a distributed manner, such as byserial-parallel conversion, for example, and also outputs signals fromthe respective components of the camera head 9 to the control device 5and the transmission cable 8 in a collective manner, such as byparallel-serial conversion, for example.

The camera head control section 95 controls the operation of the camerahead 9 overall, according to signals such as a drive signal inputthrough the transmission cable 8, or an instruction signal output froman operating section by a user operation on the operating section, suchas a switch provided exposed on the outer face of the camera head 9.Additionally, the camera head control section 95 outputs informationrelated to the current state of the camera head 9 to the control device5 through the transmission cable 8.

Note that the drive section 93, the communication module 94, and thecamera head control section 95 discussed above are realized by ageneral-purpose processor such as a central processing unit (CPU)including internal memory (not illustrated) in which a program isrecorded, or by a special-purpose processor such as any of various typesof computational circuits that execute a specific function, such as anapplication-specific integrated circuit (ASIC). Additionally, an FPGA,which is a type of programmable integrated circuit, may also be used torealize the above. Note that in the case of using an FPGA, memorystoring configuration data may be provided, and the FPGA, that is, theprogrammable integrated circuit, may be configured according toconfiguration data read out from the memory.

Note that the camera head 9 or the transmission cable 8 may also includea signal processing section that performs signal processing on animaging signal generated by the communication module 94 or the imagingsection 92. Additionally, based on a reference clock generated by anoscillator (not illustrated) provided inside the camera head 9, animaging clock for driving the imaging section 92 and a driving clock fordriving the drive section 93 may be generated and output to the imagingsection 92 and the drive section 93, respectively. Furthermore, based ona synchronization signal input from the control device 5 through thetransmission cable 8, timing signals for various processes in theimaging section 92, the drive section 93, and the camera head controlsection 95 may be generated and output to the imaging section 92, thedrive section 93, and the camera head control section 95, respectively.Also, the camera head control section 95 may be provided not in thecamera head 9, but instead in the transmission cable 8 or the controldevice 5.

In the endoscopic device 1 having the configuration described above,since the intermediate unit 103 is provided between the image sensorsection 100 (holding section 102 a) and the substrate 110, when exposedto high temperature (for example, 120° C.) by a sterilization process,such as with an autoclave, the stress due to deformation of thesubstrate 110 by thermal expansion (thermal strain) is kept fromspreading from the substrate 110 to the holding section 102 a.Specifically, the stress due to the thermal expansion of the substrate110 spreads to the underfill 103 c of the intermediate unit 103, but isabsorbed by deformation of the underfill 103 c. Moreover, since thecoefficient of thermal expansion of the intermediate member 103 a is thesame or close to that of the holding section 102 a, little to no stressis transmitted to the holding section 102 a side. For this reason, theholding section 102 a is able to make a reliable electrical connectionbetween the substrate 110 and the image sensor 101, without theconnection to the intermediate member 103 a (the joined state providedby the LGA 104) being broken by stress arising in the substrate 110.Likewise, deformation due to thermal expansion of the image sensorsection 100 (holding section 102 a) similarly is kept from spreading tothe substrate 110. In contrast, in JP 2011-000346A, this thermalexpansion is not considered, and stress from the substrate (drivecircuit board) is imparted to the joint interface with the spacer andthe image sensor, thereby producing a faulty electrical connection withthe image sensor.

According to Embodiment 1 discussed above, the intermediate unit 103 isprovided between the holding unit 102 that holds the image sensor 101,and the substrate 110, and the intermediate member 103 a included in theintermediate unit 103 is formed with a material having approximately thesame coefficient of thermal expansion as the holding section 102 a ofthe holding unit 102. Consequently, even when exposed to hightemperature (for example, 120° C.) by a sterilization process, such aswith an autoclave, the stress due to deformation of the substrate 110 bythermal expansion is kept from spreading from the substrate 110 to theholding section 102 a. Thus, a reliable electrical connection may bemade between the image sensor 101 and the substrate 110, even whenexposed to high temperature.

In addition, according to Embodiment 1 above, since the connectionstructure between the holding unit 102 and the intermediate unit 103 isan LGA structure, the gap between the holding unit 102 and theintermediate unit 103 may be reduced, and the configuration of theimaging section 92 may be made thinner.

Additionally, according to Embodiment 1 above, since the electricalconnection between the intermediate member 103 a and the substrate 110is made with a ball grid array (BGA) structure using the solder balls103 b, compared to the case of using an LGA structure, for example, thegap between the intermediate member 103 a and the substrate 110 may beincreased, thereby increasing the volume in which the underfill 103 c isused, and making it possible to improve workability related to thefilling of the underfill 103 c and the like, while also obtaining evenmore reliably the stress-absorbing advantages provided by the underfill103 c. For example, when using the solder balls 103 b, the distancebetween the intermediate member 103 a and the substrate 110 is 400 μm,whereas when using an LGA structure, the distance between theintermediate member 103 a and the substrate 110 is approximately 40 μm.

Also, according to Embodiment 1 above, since the intermediate member 103a is provided between the image sensor section 100 and the substrate110, compared to the case of directly joining the image sensor section100 and the substrate 110, the interval between the image sensor section100 and the substrate 110 becomes larger, and the workability related tothe assembly of the imaging section 92 may be improved. A lens adapter120 larger than the image sensor section 100 sometimes is affixed to theimage sensor section 100 with a thermosetting resin or the like, and theview between the image sensor section 100 and the substrate 110 maybecome narrow in some cases, but by providing the intermediate member103 a, the interval between the image sensor section 100 and thesubstrate 110 is increased, thereby ensuring the view and improvingworkability.

(Modification 1 of Embodiment 1)

Next, Modification 1 of Embodiment 1 of the present disclosure will bedescribed. FIG. 4 is a schematic diagram explaining the majorconfiguration of an imaging section according to Modification 1 ofEmbodiment 1 of the present disclosure. In Embodiment 1 above, theholding section 102 a and the intermediate unit 103 are described asbeing connected electrically by the LGA 104, but in this modification,the holding section 102 a and the intermediate unit 103 are connectedelectrically by solder balls.

In this modification, the configuration of the imaging section 92discussed earlier is provided with a ball grid array (BGA) 104A insteadof the LGA 104. The BGA 104A is realized using multiple globularelectrodes (solder balls) that electrically connect the holding unit 102and the intermediate unit 103.

Note that the solder balls used for the BGA 104A and the solder balls103 b discussed earlier may be made of solder only, but may also besolder balls including a different material, such as copper-core solderballs, in which copper is provided in the core, or resin-core solderballs, in which resin is provided in the core, for example. Note that todecrease faulty electrical connections due to a difference in thecoefficient of thermal expansion between the image sensor section 100(holding section 102 a) and the substrate 110, it is preferable to useresin-core solder balls for the BGA 104A and/or the solder balls 103 b.

Additionally, underfill similar to the underfill 103 c of theintermediate unit 103 may also be used to fill in the BGA 104A, or inother words, the space between the image sensor section 100 and theintermediate unit 103.

According to Modification 1, similarly to Embodiment 1 discussed above,the intermediate unit 103 is provided between the holding unit 102 thatholds the image sensor 101, and the substrate 110, and the intermediatemember 103 a included in the intermediate unit 103 is formed with amaterial having approximately the same coefficient of thermal expansionas the holding section 102 a of the holding unit 102. Consequently, evenwhen exposed to high temperature (for example, 120° C.) by asterilization process, such as with an autoclave, the stress due todeformation of the substrate 110 by thermal expansion is kept fromspreading from the substrate 110 to the holding section 102 a. Thus, areliable electrical connection may be made between the image sensor 101and the substrate 110, even when exposed to high temperature.

Additionally, according to Modification 1, since the BGA 104A isprovided between the image sensor section 100 and the substrate 110, thegap between the image sensor section 100 and the substrate 110 becomeseven larger compared to the LGA 104, and the workability related to theassembly of the imaging section 92 may be improved.

(Modification 2 of Embodiment 1)

Next, Modification 2 of Embodiment 1 of the present disclosure will bedescribed. FIG. 5 is a schematic diagram explaining the majorconfiguration of an imaging unit according to Modification 2 ofEmbodiment 1 of the present disclosure. In Embodiment 1 above, theintermediate unit 103 is described as including the intermediate member103 a, the solder balls 103 b, and the underfill 103 c, and is describedas electrically connecting the image sensor section 100 and thesubstrate 110 with the intermediate member 103 a and the solder balls103 b, while also using the underfill 103 c to keep stress from thesubstrate 110 from being transmitted to the image sensor section 100.However, in Modification 2, an elastic member 103 f is used toelectrically connect the image sensor section 100 and the substrate 110as well as keep stress from the substrate 110 from being transmitted tothe image sensor section 100.

In Modification 2, the configuration of the imaging section 92 discussedearlier is provided with an intermediate unit 103A instead of theintermediate unit 103 and the LGA 104, and also is provided with aholding unit 130 that holds the lens unit 91 while also supporting thelens adapter 120 and the substrate 110. The lens adapter 120 is attachedto the holding unit 130 by screws B1 and B2.

The intermediate unit 103A includes first electrode pads 103 d thatelectrically connect to the image sensor section 100, specifically thecircuit (electrodes) of the holding section 102 a, second electrode pads103 e that electrically connect to the circuit (electrodes) of thesubstrate 110, and an elastic member 103 f allowing electricalconnection between the first electrode pads 103 d and the secondelectrode pads 103 e, while also being elastically deformable. Theelastic member 103 f is formed using a conductive material, such as aconductive metal or alloy, for example, and is formed by curving abelt-shaped member. Note that the elastic member 103 f is not limited tothe above insofar as the elastic member 103 f is conductive and elastic,and may also be a conductive coil spring, for example.

The holding unit 130 holds the lens unit 91, and includes a holdingsection 131 that holds the lens adapter 120 via screws B1 and B2, andmultiple support members 132 provided between the holding section 131and the substrate 110 that support the substrate 110 with respect to theholding unit 130. The support members 132 are attached to the substrate110 by screws B3 and B4.

In the endoscopic device having the configuration described above, sincethe intermediate unit 103A including the conductive elastic member 103 fis provided between the holding unit 102 that holds the image sensor 101and the substrate 110, when exposed to high temperature (for example,120° C.) by a sterilization process, such as with an autoclave, thestress due to deformation of the substrate 110 by thermal expansion iskept from spreading from the substrate 110 to the holding section 102 a.Specifically, the stress produced by the thermal expansion of thesubstrate 110 is absorbed by elastic deformation of the elastic member103 f of the intermediate unit 103A, with little to no stress beingtransmitted to the holding section 102 a side. For this reason, theholding section 102 a is able to make a reliable electrical connectionbetween the substrate 110 and the image sensor 101, without theconnection to the intermediate unit 103A being broken by stress from thesubstrate 110.

According to Modification 2, the elastic member 103 f having conductiveand elastic properties is provided between the holding unit 102 thatholds the image sensor 101, and the substrate 110, thereby electricallyconnecting the image sensor section 100 and the substrate 110 while alsokeeping stress from the substrate 110 from being transmitted to theimage sensor section 100. Thus, a reliable electrical connection betweenthe image sensor 101 and the substrate 110 may be made, even whenexposed to high temperature.

(Modification 3 of Embodiment 1)

Next, Modification 3 of Embodiment 1 of the present disclosure will bedescribed. FIG. 6 is a schematic diagram explaining the majorconfiguration of an imaging unit according to Modification 3 ofEmbodiment 1 of the present disclosure. In Modification 2 above, theintermediate unit 103A is described as including the first electrodepads 103 d, the second electrode pads 103 e, and the elastic member 103f, but in Modification 2, an intermediate member 103 g is provided inaddition to the configuration of the intermediate unit 103A.

In Modification 3, the configuration of the imaging section 92 discussedearlier is provided with an intermediate unit 103B instead of theintermediate unit 103A. The intermediate unit 103B includes the firstelectrode pads 103 d, the second electrode pads 103 e, and the elasticmember 103 f discussed above, as well as an intermediate member 103 g.

The intermediate member 103 g, similarly to the intermediate member 103a discussed earlier, is provided internally with electricalinterconnects, enabling an electrical connection between the imagesensor 101 and the substrate 110. The intermediate member 103 g isformed using a material having a glass transition temperature of 120° C.or more, and the same coefficient of thermal expansion as the imagesensor section 100, or a coefficient of thermal expansion that is closeto the image sensor section 100 from between the image sensor section100 and the substrate 110. Specifically, the intermediate member 103 gis formed using a material having a coefficient of thermal expansionwhose value is 95% or greater than the coefficient of thermal expansionof the holding section 102 a, and also less than or equal to anintermediate value between the coefficient of thermal expansion of theholding section 102 a and the coefficient of thermal expansion of thesubstrate 110.

The holding unit 130 holds the lens unit 91, and includes a holdingsection 131 that holds the lens adapter 120 via screws B1 and B2, andmultiple support members 132 provided between the holding section 131and the substrate 110 that support the substrate 110 with respect to theholding unit 130. The support members 132 are attached to the substrate110 by screws B3 and B4.

In the endoscopic device having the configuration described above, sincethe intermediate unit 103B including the conductive elastic member 103 fis provided between the holding unit 102 that holds the image sensor 101and the substrate 110, when exposed to high temperature (for example,120° C.) by a sterilization process, such as with an autoclave, thestress due to deformation of the substrate 110 by thermal expansion iskept from spreading from the substrate 110 to the holding section 102 a.Specifically, the stress produced by the thermal expansion of thesubstrate 110 is absorbed by elastic deformation of the elastic member103 f of the intermediate unit 103B, with little to no stress beingtransmitted to the holding section 102 a side. For this reason, theholding section 102 a is able to make a reliable electrical connectionbetween the substrate 110 and the image sensor 101, without theconnection to the intermediate unit 103B (the joined state provided bythe LGA 104) being broken by stress from the substrate 110.

According to Modification 3, the elastic member 103 f having conductiveand elastic properties is provided between the holding unit 102 thatholds the image sensor 101, and the substrate 110, thereby electricallyconnecting the image sensor section 100 and the substrate 110 while alsokeeping stress from the substrate 110 from being transmitted to theimage sensor section 100. Thus, a reliable electrical connection betweenthe image sensor 101 and the substrate 110 may be made, even whenexposed to high temperature.

(Embodiment 2)

Next, Embodiment 2 of the present disclosure will be described. FIG. 7is a diagram illustrating a schematic configuration of an endoscopicdevice 1 a according to Embodiment 2 of the present disclosure.Embodiment 1 above describes an endoscopic device 1 using a rigid scopeas the endoscope 2, but the configuration is not limited thereto, and anendoscopic device using a flexible scope as the endoscope 2 is alsoacceptable. Embodiment 2 describes an example of a case in which animaging section is provided on the leading end of the insertion sectionof a flexible endoscope.

The endoscopic device 1 a is equipped with an endoscope 20 that, byinserting an insertion section 201 inside a test subject's body,captures an internal image of an observation site and generates anelectrical signal, a light source device 21 that produces illuminatinglight that radiates from the leading end of the endoscope 20, a controldevice 22 that performs certain image processing on the electricalsignal acquired by the endoscope 20 and also centrally controls theoperations of the endoscopic device 1 a as a whole, and a display device23 that displays an internal image processed by the control device 22.The endoscopic device 1 a inserts the insertion section 201 inside thebody of a test subject, such as a patient, and acquires an internalimage of the inside of the test subject's body.

The endoscope 20 is equipped with a flexible insertion section 201having a long and narrow shape, an operating section 202, connected tothe base end side of the insertion section 201, that accepts the inputof various operation signals, and a universal cord 203 which extendsfrom the operating section 202 in a different direction from thedirection in which the insertion section 201 extends, and which housesvarious cables that connect to the light source device 21 and thecontrol device 22.

The insertion section 201 includes a leading end section 204 that housesthe imaging section 92 according to Embodiment 1 discussed earlier, afreely bendable curved section 205 made up of multiple curve joints, anda flexible tube section 206 connected to the base end side of the curvedsection 205 and having a flexible elongated shape.

Likewise in the endoscopic device 1 a having the above configuration,and similarly to the endoscopic device 1 discussed earlier, if theimaging section 92 is provided in the leading end section 204, even whenexposed to high temperature (for example, 120° C.) by a sterilizationprocess, such as with an autoclave, the stress due to deformation of thesubstrate 110 by thermal expansion is kept from spreading from thesubstrate 110 to the holding section 102 a. Thus, a reliable electricalconnection may be made between the image sensor 101 and the substrate110, even when exposed to high temperature.

(Embodiment 3)

Next, Embodiment 3 of the present disclosure will be described. InEmbodiment 1, the exchange of electrical signals, the supply of power,the connection to ground, and the like between the camera head 9 and thecontrol device 5 are conducted by multiple electrical interconnectsprovided in the transmission cable 8, but in Embodiment 3, an opticalsignal is used for at least some signals transmitted and receivedbetween the camera head 9 and the control device 5, such as an imagingsignal transmitted from the camera head 9 to the control device 5, forexample.

FIG. 8 is a diagram illustrating a schematic configuration of anendoscopic device 1A according to Embodiment 3 of the presentdisclosure. FIG. 9 is an exploded perspective view of a plug 8C and areceptacle 5B to be discussed later, as viewed from the base end side(camera head 9 side) of the plug 8C. FIG. 10 is a cross-section view cutalong a plane passing through a central axis A×A in the direction inwhich the plug 8C and the receptacle 5B connect. Structural elementswhich are the same as structural elements discussed earlier will bedenoted with the same signs. The endoscopic device 1A is equipped withan endoscope 2, an imaging device 3, a display device 4, a controldevice 5, and a light source device 6. The imaging device 3 is equippedwith a transmission cable 8 and a camera head 9.

The transmission cable 8 is equipped with a cable section 8A, aconnector 8B, and a plug 8C. The cable section 8A is a composite cableincluding, inside the inner part of an outer sheath (not illustrated)that acts as the outermost layer, an optical fiber 8A1, which is anoptical transmission line that transmits optical signals such as imagingsignals, for example, and multiple electrical cables 8A2, which are usedto transmit and receive other electrical signals, supply power, connectto ground, and the like. Additionally, one end of the cable section 8Ais connected to the camera head 9 through the connector 8B.

The plug 8C is a male connector, and corresponds to an optical connectoraccording to an embodiment of the present disclosure. Additionally, theplug 8C is attached to the other end of the cable section 8A.

The receptacle 5B is a female connector provided on a housing 5A of thecontrol device 5, and corresponds to an opposite connector.

By connecting the above plug 8C and the receptacle 5B to each other, theimaging device 3 and the control device 5 become connected bothoptically and electrically, thereby enabling the exchange of opticalsignals and electrical signals, the supply of power, and the connectionto ground.

Next, the configuration of the plug 8C and the receptacle 5B will bedescribed. The plug 8C is equipped with a plug-side first outer edge 81,a plug-side cover member 82, a plug-side collimator 83, a plug-sidesecond outer edge 84, a connector section 85, a plug-side printedcircuit board 86, and an elastic member 87.

As illustrated in FIGS. 9 and 10, the plug-side first outer edge 81 hasan approximately cylindrical tube shape. Note that the plug-side firstouter edge 81 is tubular, but is not limited to being cylindrical, andmay also be configured as a tube having an elliptical, square,polygonal, or some other cross-sectional shape. Additionally, an opticalfiber 8A1 constituting the cable section 8A is inserted through theplug-side first outer edge 81 inside the tube of the plug-side firstouter edge 81, and the plug-side first outer edge 81 covers thelight-emitting end of the optical fiber 8A1 from which an optical signalis emitted.

The plug-side cover member 82 is provided to cover the tube of theplug-side first outer edge 81, and is formed in a plate-like shape froma material that transmits light. The plug-side cover member 82 is joinedairtight to the plug-side first outer edge 81 by soldering, brazing, orglass encapsulation. By sealing the leading end side of the plug-sidefirst outer edge 81 with the plug-side cover member 82, the intrusion ofliquid or foreign matter inside the plug-side first outer edge 81 may berestrained, and reliability of optical communication may be ensured.

The plug-side cover member 82 is positioned at a position retracted fromthe leading end of the plug-side first outer edge 81 toward the base endside of the plug-side first outer edge 81 (a position set back from theleading end). For this reason, the plug-side cover member 82 isstructured to be less likely touched by hand, and the adhesion offoreign matter onto the plug-side cover member 82 may be restrained. Inother words, the reliability of optical communication is not impaired bysuch foreign matter.

As illustrated in FIG. 10, the plug-side collimator 83 is disposed in astate joined to the light-emitting end of the optical fiber 8A1 insidethe plug-side first outer edge 81. In other words, the plug-sidecollimator 83 is disposed between the plug-side cover member 82 and thelight-emitting end of the optical fiber 8A1. Additionally, the plug-sidecollimator 83 collimates the light (optical signal) emitted from thelight-emitting end of the optical fiber 8A1.

In the case of disposing the plug-side collimator 83, the mechanicalconnection with the receptacle 5B does not have to be as precisecompared to a configuration that omits the plug-side collimator 83,thereby making fabrication of the plug 8C easier.

As illustrated in FIG. 10, the plug-side second outer edge 84 isequipped with a leading end side outer edge 841 and a base end sideouter edge 842, and has an approximately cylindrical shape. Note thatthe plug-side second outer edge 84 is tubular, but is not limited tobeing cylindrical, and may also be configured as a tube having anelliptical, square, polygonal, or some other cross-sectional shape.

The leading end side outer edge 841 is provided with a base section 841Amade from a non-conductive material, and multiple plug-side electricalcontact points 841C made from a conductive material. As illustrated inFIG. 10, the plug-side electrical contact points 841C are providedpartially exposed on the outer circumferential surface of the basesection 841A. The multiple plug-side electrical contact points 841C arearranged at a certain interval in the circumferential direction of theleading end side outer edge 841.

In addition, the base end portion of the plug-side first outer edge 81fits into the leading end side outer edge 841 so that the leading endportion of the plug-side first outer edge 81 projects outward. At thispoint, the space between the leading end side outer edge 841 and theplug-side first outer edge 81 is sealed with an O-ring, or with anadhesive sealant such as silicon resin or epoxy resin.

The base end side outer edge 842 is disposed on the base end side withrespect to the leading end side outer edge 841. Additionally, theleading end portion of the base end side outer edge 842 fits against thebase end side of the leading end side outer edge 841, with the cablesection 8A internally inserted therethrough. At this point, the spacebetween the base end side outer edge 842 and the leading end side outeredge 841 is sealed with an O-ring, or with an adhesive sealant such assilicon resin or epoxy resin.

As illustrated in FIG. 10, the connector section 85 is disposed insidethe base end side outer edge 842, and bridges (electrically connects)the multiple plug-side electrical contact points 841C and the plug-sideprinted circuit board 86. The connector section 85 is equipped with aflat insulator 851 including a hole 851A through which the optical fiber8A1 is inserted, and multiple contacts (not illustrated) made ofconductive material that penetrate the insulator front-to-back. Themultiple contacts electrically connect to each of the multiple plug-sideelectrical contact points 841C projecting out from the base end side ofthe leading end side outer edge 841, and also electrically connect tothe plug-side printed circuit board 86, either directly or throughconnectors (not illustrated) and electrical interconnects 88.

As illustrated in FIG. 10, the plug-side printed circuit board 86 isdisposed in a plane that includes the central axis A×A, and bridges themultiple plug-side electrical contact points 841C and the multipleelectrical cables 8A2 that constitute the cable section 8A.

The elastic member 87 is a member that inhibits twisting of the cablesection 8A around the inner edge perimeter of the base end portion ofthe base end side outer edge 842. Additionally, the leading end portionof the elastic member 87 fits into the base end portion of the base endside outer edge 842, with the cable section 8A internally insertedtherethrough. At this point, the space between the elastic member 87 andthe base end side outer edge 842 is sealed with an O-ring, or with anadhesive sealant such as silicon resin or epoxy resin.

As illustrated in FIG. 9 or 10, the receptacle 5B is equipped with areceptacle-side first outer edge 511, a receptacle-side cover member 512(FIG. 10), a receptacle-side collimator 513, a receptacle-side secondouter edge 514, and a receptacle-side printed circuit board 515.

The receptacle-side first outer edge 511 has a tubular shape in whichare formed integrally a tubular large hole section 511A, which ispositioned on the leading end side (the side that connects to the plug8C), and a tubular small hole section 511B, which is positioned on thebase end side and which has smaller inner hole dimensions that the innerhole dimensions of the large hole section 511A. Note that thereceptacle-side first outer edge 511 is tubular, but is not limited tobeing cylindrical, and may also be configured as a tube having anelliptical, square, polygonal, or some other cross-sectional shape.

The large hole section 511A is formed so that the inner hole dimensionsare slightly larger than the outer circumferential dimensions of theplug-side first outer edge 81. Additionally, the large hole section 511Ais formed so that the lengthwise dimension (the dimension in the heightdirection of the tube) is slightly larger than the projection dimensionfrom the plug-side second outer edge 84 (leading end side outer edge841) on the plug-side first outer edge 81.

The receptacle-side cover member 512 is made of an optically transparentplate, placed against the step portion of the large hole section 511Aand the small hole section 511B, and joined to the receptacle-side firstouter edge 511. Note that the joining method may adopt the same joiningmethod as the method of joining the plug-side cover member 82 to theplug-side first outer edge 81, or adopt a different joining method.Also, the receptacle-side cover member 512 may be made of the samematerial as the plug-side cover member 82, or may be made of a differentmaterial if the material has an optical transmittance by which opticalcommunication may be established.

As illustrated in FIG. 10, the receptacle-side collimator 513 isinserted through the small hole section 511B. Additionally, thereceptacle-side collimator 513 guides light (an optical signal) emittedfrom the plug-side collimator 83 to an internal circuit of the controldevice 5 through an optical fiber 55 (FIG. 10) that acts as an opticaltransmission line, for example.

In the case of disposing the receptacle-side collimator 513, themechanical connection with the plug 8C does not have to be as precisecompared to a configuration that omits the receptacle-side cover member512, thereby making fabrication of the receptacle 5B easier.

The inner perimeter of the receptacle-side second outer edge 514 has atubular shape allowing the insertion of the plug-side second outer edge84. Additionally, the leading end portion of the receptacle-side firstouter edge 511 is inserted into the receptacle-side second outer edge514 so that the base end portion projects outward.

The receptacle-side printed circuit board 515 is equipped with a boardbody 515A and multiple receptacle-side electrical contacts 515B.

As illustrated in FIG. 10, the board body 515A includes a hole 515C thatpenetrates front-to-back in an approximate center portion. Additionally,the receptacle-side first outer edge 511 fits into the hole 515C.

The multiple receptacle-side electrical contacts 515B are made from aconductive material to electrically connect to the board body 515A, andalso project into the tube of the receptacle-side second outer edge 514.The receptacle-side electrical contacts 515B are arranged at a certaininterval in the circumferential direction of the receptacle-side firstouter edge 511.

Additionally, the board body 515A bridges the multiple receptacle-sideelectrical contacts 515B and an internal circuit of the control device 5through multiple electrical cables 56 (FIG. 10), for example.

In the state in which the plug 8C and the receptacle 5B discussed aboveare mechanically connected to each other, the plug-side first outer edge81 is inserted into the receptacle-side first outer edge 511 (large holesection 511A). Additionally, in this state, the plug-side collimator 83(the light-emitting end of the optical fiber 8A1) and thereceptacle-side collimator 513 (the light-incident end of the opticalfiber 55) face each other. In other words, this state is one in which anoptical signal (imaging signal) output from the camera head 9 throughthe cable section 8A (optical fiber 8A1) is transmittable to an internalcircuit of the control device 5 through the plug 8C and the receptacle5B (a state enabling optical communication).

Additionally, in the state in which the plug 8C and the receptacle 5Bare mechanically connected to each other, the plug-side second outeredge 84 is inserted into the receptacle-side second outer edge 514, andthe multiple plug-side electrical contact points 841C are electricallyconnected to the multiple receptacle-side electrical contacts 515B,respectively. Additionally, in this state, controls signals, suppliedpower, and the like output from an internal circuit of the controldevice 5 are transmittable to the transmission cable 8 (camera head 9)through the receptacle 5B and the plug 8C.

FIG. 11 is a diagram illustrating the major configuration of anendoscopic device according to Embodiment 3 of the present disclosure,and is an exploded perspective view illustrating the configuration ofthe plug 8C of the endoscopic device 1A illustrated in FIG. 8. FIG. 12is a diagram illustrating the major configuration of an endoscopicdevice according to Embodiment 3 of the present disclosure, and is apartial cross-section view illustrating the configuration of the plug 8Cof the endoscopic device 1A illustrated in FIG. 8. The cross-sectionview illustrated in FIG. 12 is a partial cross-section view taking aplane approximately parallel to the central axis A×A as thecross-section.

As illustrated in FIGS. 10 to 12, the plug 8C additionally includes aprotective case 89 which is supported by the plug-side printed circuitboard 86, and which protects the optical fiber 8A1 passing over theboard. The optical fiber 8A1 is inserted through the hollow space formedby the faces of the protective case 89 and the plug-side printed circuitboard 86 facing each other.

The protective case 89 is formed by press-working SUS, for example. Theprotective case 89 is screwed onto the plug-side printed circuit board86, for example. By pressing and securing the protective case 89 ontothe plug-side printed circuit board 86, the formation of a gap betweenthe protective case 89 and the plug-side printed circuit board 86 isinhibited, thereby enabling the optical fiber 8A1 to be disposed withoutbeing caught in a gap formed between the protective case 89 and theplug-side printed circuit board 86. Note that the protective case 89 maybe formed using a resin, such as polyphenylene sulfide (PPS), forexample, may be formed by cutting metal, or may be formed with acomposite material of resin and metal.

Additionally, as illustrated in FIG. 12, the optical fiber 8A1 is curvedso as to draw a circle while being guided by the inner wall of theprotective case 89, with any extra length of the optical fiber 8A1wrapping around. This wraparound portion absorbs force in the extensiondirection of the optical fiber 8A1 when the transmission cable 8 is bentor twisted. Herein, the inner wall of the protective case 89 accordingto Embodiment 3 includes planar sections 891 to 894 extending in tangentdirections to the direction by which the optical fiber 8A1 is wrappedaround. Consequently, the optical fiber 8A1 may be wrapped around morestably.

According to Embodiment 3 discussed above, the protective case 89 thatprotects the optical fiber 8A1 passing over the plug-side printedcircuit board 86 is including, thereby providing a configuration relatedto the protection of the optical fiber 8A1. In addition, the formationof a gap between the protective case 89 and the plug-side printedcircuit board 86 is inhibited, the protective case 89 is easilyfabricated, and the protective case 89 may be attached easily andreliably.

In addition, according to Embodiment 3, parts of the inner walls of theprotective case 89 form planar sections 891 to 894 extending in tangentdirections to the wraparound direction of the optical fiber 8A1.Consequently, when wrapping around extra length of the optical fiber 8A1on the protective case 89, the optical fiber 8A1 may be wrapped aroundmore smoothly and the shape of the wrap may be maintained bettercompared to a configuration in which the wall faces form corners.

The foregoing thus describes embodiment for carrying out the presentdisclosure, but the present disclosure should not be limited only to theembodiments discussed in the foregoing. In the foregoing embodiments,the control device 5 is described as conducting signal processing andthe like, but such signal processing may also be conducted on the camerahead 9 side.

Herein, in the foregoing Embodiments 1 and 2 as well as Modifications 1to 3, the size of the image sensor section 100 used in the camera head 9is from 8×6 (mm) to 50×40 (mm), for example, but the size of the imagesensor section 100 provided in the leading end section 204 of theendoscopic device 1 a is from 2×2 (mm) to 6×6 (mm), for example. Theimage sensor section 100 used in the camera head 9 is large compared tothe size of the image sensor section in the endoscopic device 1 a whichis a flexible scope, and the deformation due to thermal expansion islarge. For this reason, the configuration of the imaging section 92according to the foregoing Embodiment 1 is considered to be particularlyeffective for the image sensor section 100 used in the camera head 9.

As above, a medical imaging device and endoscopic device according to anembodiment of the present disclosure is useful for making a reliableelectrical connection between an image sensor and a substrate, even whenexposed to high temperature.

It should be understood by those skilled in the art that variousmodifications, combinations, sub-combinations and alterations may occurdepending on design requirements and other factors insofar as they arewithin the scope of the appended claims or the equivalents thereof.

What is claimed is:
 1. An endoscopic device, comprising: an image sensorconfigured to sense and convert light into one or more electricalsignals; a substrate that is electrically connected to the image sensor;and an intermediate layer, interposed between the image sensor and thesubstrate, that electrically connects the image sensor and thesubstrate, wherein the intermediate layer includes an intermediatemember formed using a material having a first coefficient of thermalexpansion whose value is 95% or greater than a second coefficient ofthermal expansion of the image sensor, and also less than or equal to anintermediate value between the second coefficient of thermal expansionof the image sensor and a third coefficient of thermal expansion of thesubstrate wherein the intermediate layer additionally includes solderballs that electrically connect the intermediate member and thesubstrate, and underfill, provided between the intermediate member andthe substrate, that secures the intermediate member and the substrate,wherein the underfill is a material with less elasticity than theintermediate member and the substrate.
 2. The endoscopic deviceaccording to claim 1, further comprising: solder balls that electricallyconnect the image sensor and the intermediate member.
 3. The endoscopicdevice according to claim 1, wherein the underfill formed using amaterial having a coefficient of thermal expansion with a value betweenthe coefficient of thermal expansion of the intermediate member and thecoefficient of thermal expansion of the substrate.